DE112008002845T5 - System and method for backing up processor memory during a power failure - Google Patents

Abstract

A method of backing up processor memory, the processor configured to be powered by an external source, the method comprising:
Determining a drop of a first energy to power the processor;
Generating a reset signal when the drop falls below a threshold;
Supplying a second energy from a memory to the processor based on the reset signal; and
Maintaining the reset signal until the first energy rises above the threshold.

Description

background

embodiments The invention includes a system for securing processor memory while a power failure.

Becomes a circuit disconnected, such as in a situation a blown fuse, or is the circuit by a Short circuited short to ground, this can lead to a power failure.

During one Power failures, microprocessors are usually unable to their exits and to maintain their contents of the store. Then be Reset microprocessors, resulting in a loss of outputs and the memory leads.

Usual solutions to the problem A power failure involves the use of multiple so-called SMDs ( "Surface mount devices "), such as capacitors or a single aluminum electrolytic capacitor with a high capacity for through-hole mounting, connected to the supply input of a Voltage regulator. These solutions are usually expensive and need relatively large Areas of the Printed Circuit Board ("PCB"). For example, includes the use of a switchable aluminum electrolytic capacitor with high capacity For through-hole mounting, the manual insertion of the capacitor and the processes of a wave soldering, which increases the production cost of such circuits. In another Example requires the use of multiple SMDs that ensured is that these are oriented exactly and correctly on the printed circuit board soldered be what an extra manual or automatic optical control (Automatic Optical Inspection, AOI) and therefore the use of other areas of the printed circuit board conditional to possible shadow effects with the automatic optical control to avoid.

Summary

One The aim of the invention is that the outputs of a voltage regulator can maintain a minimum output voltage, so that the integrity of a microprocessor RAM area in the event of a battery failure preserved. Such cases can occur in the automotive sector. Many automakers require that electronic modules manufactured by component suppliers are designed to provide a solution to such cases.

In an embodiment The invention provides a method for securing processor memory provided, wherein the processor is adapted to from to be powered by an external source. The procedure involves determining a drop in a first energy, which is provided to the processor. The procedure includes the generation of a reset signal when the drop below a threshold falls. The method further includes providing a second one Energy for the processor by an energy storage based on the reset signal, and maintaining the reset signal until the first power over the Threshold increases.

A another embodiment The invention includes a circuit for securing processor memory. The circuit includes a voltage regulator, a switch, and a comparator. The voltage regulator is designed to be a to get first energy from an external source based on The first energy to provide energy to the processor, the level determine the first energy provided to the processor, and generate a reset signal when the level of the first energy falls below a threshold. The switch is connected to the voltage regulator. The desk is adapted to be activated based on the reset signal, and via the Voltage regulator to supply the processor with a second energy. Of the Comparator is connected to the switch and is designed to compare the first energy and the threshold, and the reset signal to hold until the first energy rises above the threshold.

In a further embodiment of the invention, a method for securing processor memory is provided. The method includes providing a first energy to the processor and storing at least a portion of the first energy in a memory. The method also includes detecting a drop in the first energy to be supplied to the processor, generating a reset signal when falling below a threshold, and connecting the memory to the processor, when the reset signal is active. The method further includes providing a second energy through the memory to the processor and holding the reset signal at an active level until the first energy rises above the threshold.

In a further embodiment The invention provides a circuit for securing processor memory presented. The circuit includes a voltage regulator, a Memory, a switch and a comparator. The voltage regulator is designed to receive a first energy from an external source to get energy based on the first energy the processor provide a level of the first energy supplied to the processor to determine and generate a reset signal when the level of first energy falls below a threshold. The store is to trained to store auxiliary power. The switch is designed to connect the memory to the voltage regulator when the reset signal is activated, and a second energy from the memory via the Supply voltage regulator to the processor. The comparator is connected with the switch and is designed to be the first energy and to compare the threshold, and the reset signal so long hold until the level of the first energy rises above the threshold.

In a further embodiment The invention includes a method for securing the output of a Processor. The method includes connecting an associated one Storage capacitor after a RESET signal (eg., Usually at an active low signal). The RESET signal is based on the sampling of an input supply voltage and an output voltage generated. After a RESET signal has been generated and fed to the processor, the processor goes into a known state. Anyhow sets a triggering of the RESET signal all outputs and memory of the processor back. The triggering of the RESET after the RESET signal is generated results in a Loss of outputs and the data of the processor. The procedure includes insofar also a repression a trigger of the RESET signal until the input supply voltage returns to a level where the outputs of the processor can be maintained.

The Accordingly, embodiments described in detail herein solutions ready to control the power provided to the processor and a RESET signal to the processor can be suppressed. And it will be solutions provided with which the size of a integrated emergency energy storage can be determined. To this Way can the embodiments reduce the cost of the invention, the required area of a printed circuit board reduce a number of factors that affect the circuit performance impact, reduce, increase reliability, and improve the circuit performance. In a special embodiment The invention is instead of a series circuit of three SMD capacitors each 330 uF or a single aluminum electrolytic capacitor for through hole mounting with 1000 uF a single SMD capacitor used at 33 uF.

Further Aspects of the invention will become apparent by including the detailed Description and the associated Drawings.

Brief description of the drawings

1 shows a schematic plan view of an exemplary vehicle.

2 shows an exemplary block diagram of a reset protection module 1 ,

3 shows an exemplary circuit diagram of a reset protection module 1 ,

Detailed description

marriage one of the embodiments the invention is described in detail, it is to be taken for granted, that the invention is not limited in its application by the details of Construction and arrangement of components, as shown in the following Description can be found or shown in the following drawings are limited becomes. The invention is suitable for other embodiments and is suitable to be practiced or executed in various ways.

It should also be apparent to those skilled in the art that the systems shown in the figures are models of actual, possible arrangements. Many of the described modules and logic structures may be implemented in software and executed by a microprocessor or similar device. Or the described modules and logical structures can be made using different compo components, such as application specific integrated circuits (ASIC), are implemented in hardware. Terms such as "processor" may include hardware and / or software on both sides or hardware and / or software on both sides. In addition, the description uses uppercase terms in the description. Such terms are used to conform to common practice and to help the description correlate with the drawings. However, the use of capitalization does not imply any special meaning and no specific meaning should be derived from it. Therefore, the claims should not be limited to the specific examples or the specialized vocabulary.

embodiments of the invention include a method and system for securing a voltage output of a memory of a microprocessor during a Power outage. In a special form, the circuit includes a Circuit for sampling a voltage of a power supply and a circuit for sampling an output voltage. As soon as the Recognizes circuit for sensing the voltage of the power supply, that the power supply for a period of time falls below a voltage threshold, so will be a RESET signal for generates the microprocessor. A circuit for suppressing a Resets suppressed the trigger of the RESET signal until the supply voltage is at an acceptable level Level returns.

1 shows a schematic model of an exemplary vehicle 100 , The vehicle 100 has four wheels 104A . 104B . 104C , and 104D , The wheels 104A . 104B . 104C , and 104D be from multiple wheel sensors 112A . 112B . 112C , and 112D supervised. The wheel sensors 112A . 112B . 112c , and 112D are with a processor, an electronic process unit or an electronic control unit ("ECU") 116 connected. Even though 1 only the wheel sensors 112A . 112B . 112C . 112D shows, so in the vehicle 100 Other types of sensors may also be used, such as a seat adjustment sensor, retainer sensors, sunroof sensors, and windshield wiper sensors. In the embodiment shown provides a power supply 120 the ECU 116 via a reset protection module 124 Energy ready. Although the ECU 116 and the reset protection module 124 are represented as individual components, the ECU 116 and the reset protection module 124 be arranged together in an integrated semiconductor circuit ("IC"), ASIC or the like. As will be described in detail below, in some embodiments, depending on what is in the reset protection module 124 amount of energy to be stored, some or all of the energy storage components included in the reset protection module 124 used to run as SMDs. Although the reset protection module 124 and the ECU 116 as parts of the vehicle 100 It is understood that the use of the reset protection module 124 not limited to the vehicle area, and that the reset protection module 124 can also be used in conjunction with other microcontrollers or microprocessors.

2 shows an exemplary block diagram of the reset protection module 124 out 1 , wherein like elements are designated by like reference numerals. The energy supply 120 represents the ECU 116 via the reset protection module 124 Energy ready. In the embodiment shown, the reset protection module comprises 124 an energy control unit 204 which is connected and an energy signal from the power supply 120 can receive. It should be noted that an energy signal used herein may include electrical signals such as voltage signals or current signals. The energy control unit 204 includes an energy signal controller 208 that regulates the received energy signal. The energy control unit 204 includes an energy signal comparator 212 that compares the received energy signal with a power drop threshold. When the received signal is below the threshold, the reset protection module becomes 124 considered severed. In a specific embodiment, the reset protection module is 124 configured to operate at an energy signal of approximately 6V and the energy drop threshold of approximately 4.6V.

If the energy signal comparator 212 detects that this is the reset protection module 124 provided energy signal is below the energy drop threshold, so generates or sends the energy signal comparator 212 a reset signal for / to a reset module 216 , where the reset module 216 the ECU 116 again in a reset state holds. Meanwhile, the energy signal comparator sends 212 as well as the reset signal to a power switching module 220 that has a switch 224 activated to supply the ECU 116 with energy from a power supply 120 to an energy store 228 switch. In this way, the ECU 116 through the energy storage 228 energized. In the embodiment shown also includes a supply module 232 Energy from the power supply 120 and loads the energy store 228 , In such a case, the supply module limits 232 the inrush current generated by the reset protection module 124 flows. In other embodiments, the supply module relates 232 Energy from a charge pump 236 to the amount of energy that the supply module 232 can take, control / limit or limit.

If the ECU 116 through the energy storage 228 is energized, so can the energy control unit 204 disable the reset signal, causing a loss of memory or data in the ECU 116 leads. To the energy control unit 204 to prevent the deactivation of the reset signal includes the reset protection module 124 a supply comparator 240 to generate a second reset signal and this to the reset module 216 to send. In this way, the reset signal, with which the ECU remains, lingers 116 is applied, in an activated state, and that until the energy signal of the power supply 120 returns to a predetermined level.

3 shows an exemplary circuit diagram of the reset protection module 124 out 1 and 2 , In the embodiment shown, the power signal is as described above in connection with FIG 2 explained, as a voltage signal before. As explained above provides a power supply 304 the reset protection module 124 Energy ready, taking the reset protection module 124 the energy, as explained below, to the ECU 116 forwards. During normal operation is the power supply 304 with a voltage regulator 308 connected via a reverse battery protection diode D ₁ . The voltage regulator 308 generated for the ECU 116 a power supply signal V _CC or V _{supply voltage} . The voltage regulator 308 may be implemented as a linear switched mode power supply (for example, either as a buck converter or boost converter) or as a combination of two categories (eg, a boost converter / buck converter circuit coupled to a linear regulator). Further, in some embodiments, an external capacitor (not shown) is connected to the supply voltage to help provide near-instantaneous and stable current to the ECU 116 provide.

When the power supply 304 fails to provide the required voltage signal, or becomes the power supply 304 for another reason, from the reset protection module 124 disconnected, the voltage regulator receives 308 no longer the required voltage signal. The voltage regulator is corresponding 308 no longer able to do that by the ECU 116 needed to maintain supply voltage signal. Specifically, when the supply voltage signal falls below a predetermined voltage threshold necessary for proper operation of the ECU 116 is needed, then the voltage regulator generates 308 a reset signal V _{reg reset} , which is usually an active low signal.

Once generated, the voltage regulator sends 308 the reset signal V _{reg reset} to a reset circuit 316 , The reset circuit 316 also receives a supply voltage below the threshold from the voltage regulator 308 , If these two signals are received, then the reset circuit is applied 316 the ECU 116 with a signal RESET _out . Receives the ECU 116 the signal RESET _out , so goes the ECU 116 in a reset state, which is a known state of the ECU. If the signal RESET _{out is} active and the ECU is located 116 in the reset state, so will the from the ECU 116 related electricity is reduced or minimized.

The voltage regulator 308 is also via the reset signal V _{reg reset} with a switch controller 320 connected.

In the embodiment shown, the switch controller closes or activates 320 a switch S ₁ when the reset signal is active. Closes or activates the switch controller 320 the switch S ₁ , the switch controller connects 320 also a capacitor C _storage with the voltage regulator 308 , In this manner, the capacitor C is supplied with _storage of its stored energy to the voltage regulator 308 in the form of a voltage signal. The voltage regulator 308 then passes the voltage signal to the ECU 116 so that the memory contents of the ECU 116 can be maintained. In some embodiments, starting from those in the voltage regulator 308 components used to the reverse battery protection diode D _{1 are} omitted. In such cases, the switch S _{1 is} internal to the voltage regulator 308 connected. The switch S ₁ can be realized as a semiconductor device, such as bipolar NPN or PNP, as N- or P-channel CMOS or as N- or P-channel transistor DMOS, etc.

A supply circuit 324 , which is connected upstream of the capacitor C _storage and also connected to a supply node n ₁ , is _adapted to charge the capacitor C _storage . In the illustrated embodiment, the supply node n _{1 is} preferably supplied with a voltage signal V _{c supply} . In further embodiments, the supply node n ₁ receives the voltage signal V _{C Supply} from an internal charge pump circuit (not shown) to provide a current for charging the reset protection module 124 to control / regulate or limit. In other embodiments, the supply node receives n _1, the voltage signal V _{C Supply} from sources external to the reset protection module 124 , such as from the power supply 304 , In this way, the supply circuit 324 limit an inrush current and connection lines of the reset protection module 124 protect. In embodiments, an earth require final protection, it is assumed that the supply circuit 324 prevents discharge of the capacitor C _storage . In contrast, if the ground fault protection is only optional, then it is not necessary that the supply circuit 324 unloading the capacity C _storage prevented. In further embodiments, the switch S _{1 is} directly connected to the output V _{CC of} the voltage regulator 308 connected. In such a case, the supply node n _{1 is} also connected to the output V _CC voltage regulator 308 connected.

The capacitor C _storage provides a reduced amount of power to the memory contents of the ECU 116 over the voltage regulator 308 so could the voltage regulator 308 unintentionally, the voltage signal received from the capacitor C _storage as a voltage signal from the power supply 304 detect. In this case, the voltage regulator could 308 disable the reset signal that the ECU 116 holds in the known reset state. To the ECU 116 to keep in the reset state and to avoid inadvertent deactivation of the reset signal uses the reset protection module 124 a supply comparator 328 to generate an alternative reset signal V _{sup reset} and to the reset circuit 316 to send. Like the reset signal V _{reg reset} , so does the alternative reset signal V _{sup reset} the switch controller 320 supplied to ensure that the switch S _{1 is} closed. In addition, the alternative reset signal V _{sup reset} also ensures that the RESET _out signal remains active so that the ECU 116 remains in the reset state. In further embodiments, the inputs of the supply comparator 328 protected for conditions such as overvoltage or reverse polarity.

External capacitors can be used to reset the protection module 124 to prevent electrostatic discharge ("ESD") during manufacturing, module assembly, or during operation.

A reference voltage supply 332 , which is often performed with a band gap, is coupled to the supply comparator 328 to provide a reference voltage V _reference such that the supply comparator 328 the alternative reset signal V _{sup reset} for the reset circuit 316 can generate. Will the voltage regulator 308 Energy provided from the capacitor C _storage , the reference voltage V _{reference is} greater than the voltage at the node n ₂ . This generates the supply comparator 328 the alternative reset signal V _{sup reset} . In contrast, the voltage regulator 308 Energy from the power supply 304 supplied, the reference voltage V _{reference is} smaller than the voltage at the node n ₂ . In these cases, the supply comparator disables 328 the alternative reset signal V _{sup reset} . In some embodiments, filter delays and hysteresis are required to generate the V _{reg reset} and V _{sup reset} signals to prevent noise sources from inadvertently triggering the RESET _out signal or triggering the switch controller 320 to activate the switch 51 to prevent.

Equation (1) shows an exemplary equation that defines a minimum value for the capacitor C _storage .

Where C _{storage min is} a minimum capacity for the capacitor C _storage . Depending on an initial tolerance, the design (eg of the package and the dielectric), the reduction of the operating values over the lifetime and the ambient conditions of the capacitor, the value of C _storage varies _min . The value of I _{total supply} is a total amount of the current provided by C _storage once the switch S _{1 is} closed, and includes one of the ECU 116 supplied amount of electricity and amounts of electricity from the switch controller 320 , the reference voltage V _reference , the supply comparator 328 and the voltage regulator 308 consumed. A key factor in determining a value of I _{total supply} is that of the ECU 116 amount of electricity supplied. Therefore, with a reduction to the ECU 116 supplied amount of current reduces the value of the capacitor C _storage . Although there is a loss of current due to the inherent loss of the capacitor C _storage , the inherent loss when using a high quality dielectric is usually negligible. The value T _{supply loss} is a maximum time or maximum time taken by the ECU 116 required to their memory or other performance levels according to the specification of the ECU 116 of the original equipment manufacturer ("OEM"). The value V _{supply drop} is the difference between the voltage at the switch S ₁ when activated and a minimum output voltage V _CC the voltage regulator 308 after the time period T _{supply loss.} The value V _{supply drop} can be determined by equation (2) as follows.

eine Spannung an dem Kondensator C_storage ist, wenn der Schalter S₁ anfänglich geschlossen oder aktiviert ist.

ist ein benötigtes Ausgangsspannungs-Niveau der Spannung V_CC des Spannungsreglers 308 zum Zeitpunkt T_{supply loss} oder darüber hinaus. V_drops ist ein Spannungsabfall oder -verlust des Kondensators C_storage auf die Spannung V_CC durch den Spannungsregler 308. In einigen Ausführungsformen bestimmen Anforderungen der ECU 116 bezüglich des Stroms, die die Intaktheit des Speichers oder anderer erwünschter Funktionen aufrechterhalten sollen, einen Wert von

Zusätzlich bestimmen Spannungsabfälle an dem Schalter S₁ und dem Spannungsregler 308 auch einen Wert von V_drops.In which

a voltage across the capacitor C _storage is when the switch S _{1 is} initially closed or activated.

is a required output voltage level of the voltage V _{CC of} the voltage regulator 308 at time T _{supply loss} or beyond. V _drops is a voltage drop or loss of the capacitor C _storage to the voltage V _CC through the voltage regulator 308 , In some embodiments, requirements of the ECU determine 116 with respect to the current intended to maintain the integrity of the memory or other desired functions, a value of

In addition, voltage drops on the switch S ₁ and the voltage regulator determine 308 also a value of V _drops .

und V_drops in Gleichung (2) reduziert und/oder der Wert von

erhöht werden. Eine Möglichkeit zur Erhöhung des Werts

in Gleichung (2) ist nachstehend erläutert.The value of the capacitor C _storage can be reduced by increasing the denominator V _{supply drop} from equation (1). To increase the value of the denominator V _{supply drop} of equation (1) should have the corresponding values

and V _{drops are} reduced in equation (2) and / or the value of

increase. A way to increase the value

in equation (2) is explained below.

die Spannung des Kondensators C_storage ist.In some embodiments, a higher voltage at node n _{1 leads} to the supply circuit 324 connected to a higher voltage across the capacitor C _storage since

is the voltage of the capacitor C _storage.

Therefore, the node should be n ₁ with the highest the reset protection module 124 be connected to the available voltage. In some embodiments, the highest is the reset protection module 124 available voltage through the charge pump 236 (out 2 ) generated. An example of the charge pump 236 is a voltage doubler or voltage tripler circuit based on signals from the power supply 304 be generated. As explained above, the charge pump 236 together with the reset protection module 124 to get integrated. In further embodiments, the node n _{1 is connected} to V _BATT at the power supply 304 connected. In addition, one way to reduce the value of V _drops of equation (2) is to reduce the voltage _drops across the voltage regulator 308 and the switch S ₁ .

For some applications, the ECU becomes 116 for a predetermined period of time after the disconnection of the power supply 304 held at full function. In an alternative embodiment (not shown), for example, the ECU 116 be kept in full function by setting a trip point, which determines a voltage threshold above which the signal V _{sup reset is} activated, and by a modification of the corresponding reset circuit 316 and the switch controller 320 to use the V _{sup reset} signal. In the embodiment shown, the trip point of the supply comparator 328 determined by the values of the resistors R ₁ and R ₂ . In order to adjust the voltage threshold at which the signal V _{sup reset is} generated, the values of the resistors R ₁ and R ₂ are adjusted according to the equation (3) as follows.

Thus, for example, the value of R ₁ becomes approximately 1.5 times as large as the value of R ₂ when V _{reference is} approximately _2.4V and V _BATT is approximately _6.0V . Likewise, the value of R _{1 is} about three times greater than the value of R ₂ when V _reference is about _1.2V and V _BATT is about _6.0V . Also, the switch controller 320 in such an alternative embodiment only controlled / regulated by the signal V _{sup reset} .

In some embodiments, the reset protection module includes 124 an optional internal guard function or module (not shown) to prevent operational failure of the reset protection module 124 or the ECU 116 to recognize. If the internal guard function detects an operating error, the internal guard function also generates a signal V _{reg reset} to the ECU 116 due to the detected operating error reset. However, the generated signal V _{reg reset} activates the switch S ₁ , which is provided for a low voltage supply, regardless of whether the signal V _{reg reset} is generated due to a low supply voltage or an operating error. That means it with the embodiment, as in 3 shown is possible that the watchdog function and the voltage regulator 308 generate a signal V _{reg reset} which activates the switch _S1. In an alternative embodiment (not shown), the reset circuit is 316 of the 3 modified to allow a correct activation of the switch S ₁ only due to a low supply voltage. In such a case, the reset circuit has 316 of the 3 make sure that the signal V _{reg reset of} the voltage regulator 308 as well as the alternative reset signal V _{sup reset} from the supply comparator 328 are active. Are the signal V _{reg reset} from the voltage regulator 308 and the alternative reset signal V _{sup reset} from the supply comparator 328 active, so generates the reset circuit 316 an active signal RESET _out . Subsequently, the reset circuit 316 the switch S ₁ via the switch controller 320 activate.

Although the reset protection module 124 as in 3 Usually implemented as ASIC or IC, the reset protection module can 124 also be implemented with multiple circuit components in a discrete circuit on a circuit board. That way, the reset protection module can 124 be realized relatively quickly. For example, an Infineon IC TL4299EN can be used to control the voltage regulator 308 , the reference voltage supply 332 and the supply comparator 328 to implement with external resistors R ₁ and R ₂ . In such a case, the reverse battery protection diode D _{1 is} for the voltage regulator 308 optional. On the other hand, additional circuits may be needed to power the supply comparator 328 to protect.

Further Features and advantages of the invention will be apparent in the following Claims.

Summary

One Method, and a system using the method for securing from processor memory, the processor being from an external source is energized. The method includes recognizing a Waste in a first energy provided to the processor is generating a reset signal when the drop below a Threshold falls, providing a second energy from an energy store based on the reset signal, and holding the reset signal until the first energy over the threshold rises.

Claims (24)

Method for securing processor memory, wherein the processor is adapted to receive from an external Source to be powered, the method comprising: Determine a drop of a first energy to power the processor; Produce a reset signal when the drop falls below a threshold; Feeding one second energy from a memory to the processor, based on the reset signal; and Maintaining the reset signal as long as until the first energy over the threshold rises. The method of claim 1, wherein maintaining of the reset signal includes: Deriving a reference signal the second energy; Compare the reference signal with the first energy; and Generating a second reset signal, if the reference signal is greater than the first energy is. The method of claim 1, wherein the providing the second energy from a memory comprises: Activate a switch when the reset signal is activated; and Connect the memory with the processor. The method of claim 1, wherein the memory has a Capacitor includes, and wherein in the method of the capacitor is charged by a supply circuit. The method of claim 1, wherein the generation of the reset signal includes: Generating an intermediate reset signal; Activate a reset circuit with the intermediate reset signal; and Output of the reset signal from the activated reset circuit. The method of claim 1, further comprising: Deactivate of the reset signal when the first energy is above the threshold located. A circuit for backing up processor memory, the circuit comprising: a voltage regulator designed to do so is to get a first energy from an external source based on the first energy to provide energy to the processor to determine a level of the first energy supplied to the processor, and generate a reset signal when the level of the first energy falls below a threshold; one Switch connected to the voltage regulator and designed to is to be activated based on the reset signal and a second energy over supply the voltage regulator to the processor; and one to the Switch connected comparator, which is designed to compare the first energy and the threshold and the reset signal up to an increase of the first energy over the Threshold. The circuit of claim 7 including a controller for the Switch, wherein the controller is adapted to the reset signal to receive and activate the switch. The circuit of claim 7 with a reference supply, which is adapted to receive the second energy and a Derive reference signal from the second energy, and wherein the Comparator further adapted to a second reset signal to generate when the first energy below the reference signal is. The circuit of claim 7, wherein the reset signal an intermediate reset signal, and wherein the circuit further includes a reset circuit configured to be based to generate a processor reset signal on the intermediate reset signal. The circuit of claim 7, further comprising a capacitor adapted to receive the second energy store and deliver the second power to the processor. The circuit of claim 11, further comprising a supply circuit configured to charge the capacitor to load. Method for securing processor memory, wherein the method comprises: Providing a first energy to the processor; to save at least a portion of the first energy in a memory; Determine a drop in the first energy to be provided to the processor; Produce a reset signal when the drop falls below a threshold; Connect the memory with the processor when the reset signal is active; Provide a second energy from the memory for the processor; and active Holding the reset signal until the first energy rises above the threshold. The method of claim 13, wherein maintaining of the reset signal includes: Deriving a reference signal the second energy; Compare the reference signal with the first energy; and Generating a second reset signal when the reference signal is larger as the first energy. The method of claim 13, wherein providing a second energy from the memory includes: activating a switch when the reset signal is activated; and connecting the memory to the processor. The method of claim 13, wherein a capacity of one Supply circuit is loaded. The method of claim 13, wherein the generation a reset signal includes: Generating an intermediate reset signal; With the reset signal is activated a reset circuit; and Activate the reset signal from the activated reset circuit. The method of claim 13, wherein the reset signal is deactivated when the first energy above the threshold located. A circuit for backing up a processor output full a voltage regulator designed to to get a first energy from an external source based to provide energy to the processor on the first power Level of the first energy supplied to the processor, and generate a reset signal when the level of the first energy falls below a threshold; one Memory for storing auxiliary energy; a switch, which is adapted to the memory with the voltage regulator connect when the reset signal is activated and a second one Energy from the store over supply the voltage regulator to the processor; and one with the Switch connected comparator, which is adapted to the compare first energy and threshold, and the reset signal so long to maintain the level of the first energy above the threshold increases. The circuit of claim 19, further comprising a controller for the switch, wherein the controller is adapted to the reset signal to receive and activate the switch. The circuit of claim 19, further comprising a reference supply configured to receive the second energy to obtain and derive a reference signal from the second energy, and wherein the comparator is adapted to a second reset signal to generate when the first energy below the reference signal is. The circuit of claim 19, wherein the reset signal includes an intermediate reset signal, and wherein the circuit has a Includes reset circuitry that is designed based on the intermediate reset signal to generate a processor reset signal. The circuit of claim 7, wherein the memory has a Capacitor, the capacitor being designed to to save the auxiliary power and the auxiliary power to the processor supply. The circuit of claim 23, further comprising a supply circuit configured to charge the capacitor to load.